CN110658666A - Optical engine and projection display system - Google Patents

Abstract

The invention provides an optical engine and a projection display system. This application sets up at least a set of heat abstractor on the casing that is equipped with optical assembly, heat abstractor including set up in the inboard magnetism flabellum of casing, set up in the magnetic structure in the casing outside, and the drive arrangement of magnetic structure, magnetism flabellum receives the drive of magnetic structure rotates. The application utilizes Coulomb's law of magnetism, namely the magnetic field induction effect between two magnets which are closely spaced, and the power is transferred from one magnet to the other magnet through the coupling force of the magnets, so that a non-contact torque is formed. In the rotating process of the magnetic structure, the polarity is continuously changed, and the principle that like poles repel each other and opposite poles attract each other is utilized to drive the magnetic fan blades inside the shell to rotate, so that circulating air flow is generated, air flowing inside the shell is promoted, the heat exchange efficiency of air and the shell is enhanced, and the heat dissipation effect of a closed environment can be effectively enhanced.

Description

Optical engine and projection display system

Technical Field

The present disclosure relates to the field of projector technologies, and in particular, to an optical engine and a projection display system.

Background

The optical engine typically includes both a projection light source and a projection light engine. Lasers are an important component of projection light sources, and can provide a projection display system with a monochromatic light source that produces the tricolor light required to generate a display image under the action of a fluorescent wheel. The projector homogenizes and compresses the tricolor light output by the projection light source, and outputs approximately parallel light meeting the incident requirement of the light valve component, so that the light valve component modulates the tricolor light and performs subsequent projection display of the projection lens.

On one hand, the laser in the projection light source generates larger heat, and the heat is more concentrated, so that the temperature rise in the closed projection light source is faster; on the other hand, because the light density output by the projection light source is high, a part of light is absorbed and converted into heat energy, the heat energy cannot be dissipated in time in the closed projection light machine, so that the temperature rises, and after the temperature rises, optical lenses such as convex lenses in the projection light machine can expand and deform, so that the position of light rays is deviated, and the abnormal display phenomenon of the laser projection system is caused. Therefore, how to effectively reduce the internal temperature of the optical engine on the premise of not influencing the sealing performance of the optical engine is a technical problem which needs to be solved at present.

Disclosure of Invention

The embodiment of the invention provides an optical engine and a projection display system, and aims to solve the problem that in the prior art, the heat dissipation efficiency in a closed optical engine is low.

In a first aspect, the present invention provides an optical engine comprising a housing and at least one set of heat dissipation devices;

the heat dissipation device comprises a magnetic fan blade arranged on the inner side of the shell, a magnetic structure arranged on the outer side of the shell and a driving device of the magnetic structure, wherein the magnetic fan blade is driven by the magnetic structure to rotate.

In a second aspect, the present invention also provides a projection display system, which includes the optical engine.

The beneficial effect of this application is as follows:

the embodiment of the invention provides an optical engine and a projection display system. This application sets up at least a set of heat abstractor on the casing that is equipped with optical assembly, heat abstractor including set up in the inboard magnetism flabellum of casing, set up in the magnetic structure in the casing outside, and the drive arrangement of magnetic structure, magnetism flabellum receives the drive of magnetic structure rotates. The application utilizes Coulomb's law of magnetism, namely the magnetic field induction effect between two magnets which are closely spaced, and the power is transferred from one magnet to the other magnet through the coupling force of the magnets, so that a non-contact torque is formed. In the rotating process of the magnetic structure, the polarity is continuously changed, and the principle that like poles repel each other and opposite poles attract each other is utilized to drive the magnetic fan blades inside the shell to rotate, so that circulating air flow is generated, air flowing inside the shell is promoted, the heat exchange efficiency of air and the shell is enhanced, and the heat dissipation effect of a closed environment can be effectively enhanced.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the invention and together with the description, serve to explain the principles of the invention.

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without inventive exercise.

Fig. 1 is a schematic structural diagram of an optical engine according to an embodiment of the present disclosure;

fig. 2 is a schematic structural diagram of a projection light source according to an embodiment of the present disclosure;

FIG. 3 is a schematic diagram of air flow in a conventional projector;

fig. 4 is a schematic structural diagram of a projection light engine according to an embodiment of the present disclosure;

FIG. 5 is an air circulation diagram of a projection light engine according to an embodiment of the present disclosure;

fig. 6 is a schematic structural diagram of another projection optical machine according to an embodiment of the present disclosure;

fig. 7 is an air circulation diagram of another light engine according to an embodiment of the present disclosure.

Detailed Description

In order to make those skilled in the art better understand the technical solution of the present invention, the technical solution in the embodiment of the present invention will be clearly and completely described below with reference to the drawings in the embodiment of the present invention, and it is obvious that the described embodiment is only a part of the embodiment of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, a schematic structural diagram of an optical engine according to an embodiment of the present disclosure is shown. As can be seen from fig. 1, the present application provides an optical engine comprising: the heat dissipation device comprises a shell 1 and at least one group of heat dissipation devices, wherein each heat dissipation device comprises a magnetic fan blade 10, a magnetic structure 20 and a driving device 30, the magnetic fan blades 10 are arranged on the inner side of the shell 1, and the magnetic structure 20 and the driving device 30 are arranged on the outer side of the shell 1. The driving device 30 is used for driving the magnetic structure 20 to rotate, the magnetic structure 20 and the magnetic fan blade 10 both have magnetism, and the magnetic fan blade 10 can be driven by the magnetic structure 20 to rotate. In this application, the housing 1 includes not only the whole housing of the optical engine, but also the housing of the projection light source and the projection light machine which are arranged inside the optical engine.

The application utilizes Coulomb's law of magnetism, namely the magnetic field induction effect between two magnets which are closely spaced, and the power is transferred from one magnet to the other magnet through the coupling force of the magnets, so that a non-contact torque is formed. In the rotating process of the magnetic structure, the polarity is continuously changed, and the principle that like poles repel each other and opposite poles attract each other is utilized to drive the magnetic fan blades inside the shell to rotate, so that circulating air flow is generated, air flowing inside the shell is promoted, the heat exchange efficiency of air and the shell is enhanced, and the heat dissipation effect of a closed environment can be effectively enhanced.

Further, the optical engine further comprises a projection light source 101, the projection light source 101 at least comprises a first optical assembly 104 enclosed by a first sealed housing 103, and the heat sink is disposed on a side wall of the first sealed housing 103. Fig. 2 is a schematic structural diagram of a projection light source according to an embodiment of the present disclosure. As can be seen from fig. 2, the first optical assembly 104 further includes a laser 1041, a lens 1042 and a fluorescent wheel 1043, and since the laser 1041 is a main heating element of the projection light source 101, a plurality of sets of heat dissipation devices can be intensively disposed on the sidewall of the first sealing housing 103 near the laser 1041, so as to improve the heat dissipation efficiency of the projection light source 101.

Further, the optical engine further includes a light projector 102, the light projector 102 at least includes a second optical component 106 enclosed by a second sealed housing 105, and the heat sink is disposed on a sidewall of the second sealed housing 105.

Referring to fig. 3, an air flow diagram of a conventional projection light engine is shown. As can be seen from fig. 3, the light pipe 2, the lens assembly 3, and the reflector assembly 4 are main heating elements of the projection light machine 102, and in a closed housing without a heat dissipation assembly, after heat is emitted from the light pipe 2, the lens assembly 3, and the reflector assembly 4, hot air around the light pipe can only flow forward slowly in a natural convection manner along an arrow direction, and finally flows to the housing to exchange heat with external cold air, such an air flow manner results in a slow heat exchange process and low efficiency.

Fig. 4 is a schematic structural diagram of a projection optical machine according to an embodiment of the present disclosure. As can be seen from fig. 4, the projector engine 102 includes:

the second sealed housing 105, the second sealed housing 105 is a sealed metal housing, and an optical component for optical machine illumination is packaged inside the second sealed housing 105, and the optical component specifically includes a light guide 2, a lens group 3, a mirror group 4, and a TIR total reflection prism 5. The light beam within a certain angle range emitted by the projection light source is homogenized under the multiple reflection of the light guide pipe 2, the homogenized light beam generally has a certain divergence angle, and forms an approximately parallel light beam after the convergence of the lens group 3 and the turning and volume compression of the light path by the reflector group 4, and the light beam is reflected by the total reflection prism 5 and then enters the light valve component, so that the light valve component modulates the tricolor light and performs the subsequent projection display of the projection lens.

In this embodiment, at least one set of heat dissipation devices is disposed on the second sealed housing 105, and the position of the heat dissipation device may be any one sidewall of the second sealed housing 105, or may be an upper surface or a lower surface of the second sealed housing 105. The heat dissipation device mainly includes two parts, one part is disposed inside the second sealed housing 105, and the other part is disposed at a relative position outside the housing, specifically including the magnetic fan blade 10 disposed between the second sealed housing 105 and the optical component, and the magnetic structure 20 and the driving device 30 disposed outside the second sealed housing 105. Magnetic fan blade 10 is made by magnetic material, or partly by magnetic material, and similarly, magnetic structure 20 is also made by magnetic material, or partly by magnetic material, and the magnetism size and the setting position of magnetic material of both only need satisfy magnetic structure 20 and magnetic fan blade 10 can carry out effectual space transmission can.

In this embodiment, the magnetic structure 20 is a magnetic bar symmetrically disposed with respect to the center line of the second fixed shaft 62. Of course, the magnetic structure 20 may be other numbers and shapes of magnetic structures as long as they provide an alternating magnetic field during rotation.

The magnetic structure 20 and the magnetic fan blade 10 are disposed on the same side wall or the same surface of the second sealing housing 105, and are disposed in opposite positions, that is, the magnetic fan blade 10 and the magnetic structure 20 have an overlapping region in a direction perpendicular to the fixed housing, so as to ensure that the magnetic structure 20 can drive the magnetic fan blade 10 to rotate. The installation position of the driving device 30 outside the second hermetic case 105 is not limited in this embodiment as long as it is ensured that the driving device 30 can provide the magnetic structure 20 with the rotational power.

When the magnetic structure 20 is driven by the driving device 30 to rotate, the magnetic fan blade 10 can be driven by the magnetic structure 20 to rotate. In this embodiment, power is transferred from one magnet to another by the magnet coupling force, thereby creating a non-contact torque. In the rotating process of the magnetic structure, the polarity is continuously changed, and the principle that like poles repel each other and opposite poles attract each other is utilized to drive the magnetic fan blades inside the shell to rotate, so that circulating air flow is generated, air flowing inside the shell is promoted, the heat exchange efficiency of air and the shell is enhanced, and the heat dissipation effect of a closed environment can be effectively enhanced.

Further, the conventional electrically driven fan needs to be provided with a driving means, and since the second hermetic case 105 has a limited inner space, the driving means is generally required to be disposed outside the second hermetic case 105 and electrically connected to the fan through a bearing penetrating the sidewall of the second hermetic case 105. Such an arrangement increases the difficulty of sealing the second sealed housing 105, and dust is likely to enter the joint between the bearing and the second sealed housing 105, which leads to a decrease in the light conversion efficiency of the fluorescent wheel structure. In addition, there is also a scheme that a part of the driving device of the conventional fan is arranged inside the casing 1, and the driving device is easy to have a short service life and low driving reliability due to the high temperature inside the second sealing casing 105. In this application, magnetic structure 20 provides rotary power for magnetic flabellum 10 through magnetic force, and magnetic flabellum 10 and magnetic structure 20 direct contact not can effectively avoid the adverse effect to second seal housing 105 sealing performance.

In a common optical assembly, a light guide 2, a lens group 3, and a reflector group 4 are sequentially disposed along a horizontal direction, and a TIR total reflection prism 5 is disposed perpendicular to the reflector group 4. The lens group 3 is usually most affected by high temperature in the optical assembly, and since the lens group 3 belongs to the front end component in the optical conduction of the optical assembly, once the convex lens configured in the lens group 3 is expanded and deformed, the light rays of the subsequent optical assembly are all subjected to a shift phenomenon, and the shift degree is continuously accumulated along with the propagation of the light rays. For this reason, in the present embodiment, the magnetic fan 10 is disposed near the sidewall of the lens assembly 3, so that the hot air around the lens assembly 3 can be rapidly circulated.

In addition, the light guide 2 is the most dominant heat generating component in the optical module, and therefore, the temperature of the air near the light guide 2 is slightly higher than the temperature of the air at other portions in the second hermetic case 105. In the light propagation direction, the lens set 3 is connected to the light guide tube 2, and the two are located in the same horizontal plane with respect to the side wall of the housing, when the magnetic fan blade 10 is disposed on the side wall close to the lens set 3, the position of the magnetic fan blade 10 close to the light guide tube 2 is also close, so that the magnetic fan blade 10 can also effectively drive the hot air near the light guide tube 2 to enter an air circulation state, so as to exchange heat with the second sealing housing 105 as soon as possible, and reduce the air temperature in the second sealing housing 105. Therefore, in the preferred embodiment of the present application, the position of the magnetic fan 10 can be arranged corresponding to the light guide 2, that is, the magnetic fan 10 is maximally overlapped with the light guide 2 in the vertical projection direction. Of course, in order to achieve the heat dissipation of the two sets of optical components of the light guide 2 and the lens assembly 3, the preferred embodiment of the present invention can dispose the magnetic fan 10 between the light guide 2 and the lens assembly 3, so as to achieve the heat dissipation effect of the two sets of optical components.

In the present embodiment, the magnetic fan blades 10 are disposed at a position, on one hand, from the sensing element (the lens group 3), that the hot air around the lens group 3 is transmitted as a starting end of air circulation so as to exchange heat with the second sealed housing 105 as soon as possible, and at the same time, the air with a slightly lower temperature near the TIR total reflection prism 5 and other distal components can flow to the lens group 3 as soon as possible in the circulation process, so as to further reduce the air temperature at the lens group 3; on the other hand, the position of the magnetic fan blades 10 can also be considered as a main heat dissipation element, starting from the source of heat generation, the light pipe 2 and the hot air around the lens group 3 are pushed out together, so that the high-temperature air can exchange heat with the second sealed shell 105 as soon as possible, and the low-temperature air can flow to the vicinity of the lens group 3 as soon as possible.

Fig. 5 is a schematic air circulation diagram of a projection light engine according to an embodiment of the present disclosure. As can be seen from fig. 5, in the enclosed optical engine provided in this embodiment, after most of the heat is emitted from the light guide 2, the hot air around the light guide can flow rapidly under the action of the magnetic fan 10, and the air with slightly lower temperature flows to the space near the light guide 2, so as to form an air circulation path of the light guide 2 → the TIR total reflection prism 5 → the reflector group 4 → the lens group 3 → the light guide 2 according to the distribution of the optical components in the housing, thereby promoting the air flow in the housing, enhancing the heat exchange efficiency between the air and the housing, and effectively enhancing the heat dissipation effect of the enclosed environment.

Fig. 6 is a schematic structural diagram of another projection optical device according to an embodiment of the present application. As can be seen from fig. 6, the optical engine of the present embodiment includes two sets of heat dissipation devices, namely a first heat dissipation device 51 and a second heat dissipation device 52, where the first heat dissipation device 51 and the second heat dissipation device 52 are respectively disposed on two adjacent sidewalls, where the first heat dissipation device 51 is disposed near the first sidewall 11 of the lens assembly 3, and the second heat dissipation device 52 is disposed near the second sidewall 12 of the light entrance of the light guide 2. Since the density of the elements spatially arranged at the left side of the TIR total reflection prism 5 is low, and the relative air storage volume is large, in this embodiment, the second heat sink 52 is disposed at the position corresponding to the TIR total reflection prism 5 on the second side wall 12, and the shielding elements near the second heat sink 52 are few, so that the fluidity of the air in the space in front of the second heat sink 52 can be effectively promoted.

In addition, in the present embodiment, the third sidewall 13 opposite to the second sidewall 12 is generally in a step-like structure, and a sealing structure is generally disposed at the step to ensure the sealing performance of the second sealing housing 105, specifically, the third sidewall 13 includes two parallel surfaces 131 disposed parallel to the second sidewall 12 and an inclined surface 132 disposed between the two parallel surfaces, and the sealing assembly 6 is disposed at a position opposite to the inclined surface 132. Because the two side walls where the first heat dissipation device 51 and the second heat dissipation device 52 are located are perpendicular to each other, the aerodynamic directions provided by the first heat dissipation device 51 and the second heat dissipation device 52 are also perpendicular to each other, and the resultant force of the first heat dissipation device 51 and the second heat dissipation device 52 has a certain inclination angle and is just matched with the inclination direction of the inclined surface 132, which is beneficial to reducing the resistance of the air in the unreal flow.

Referring to fig. 7, an air circulation diagram of another light engine for projection according to an embodiment of the present application is shown. As can be seen from fig. 7, in the enclosed optical engine provided in this embodiment, after most of the heat is emitted from the light guide 2, the hot air around the light guide can rapidly flow along the inclined surface 132 under the action of the first heat dissipation device 51 and the second heat dissipation device 52, and the air with a slightly lower temperature flows to the space near the light guide 2, so as to form an air circulation path of the light guide 2 → the TIR total reflection prism 5 → the reflector group 4 → the lens group 3 → the light guide 2 according to the distribution of the optical components in the housing, so as to promote the air flow in the housing, enhance the heat exchange efficiency between the air and the housing, and effectively enhance the heat dissipation effect of the enclosed environment.

In this embodiment, the heat dissipation device further includes a first fixing shaft 61 and a second fixing shaft 62, wherein one end of the first fixing shaft 61 is connected to the second sealed housing 105, the other end of the first fixing shaft is connected to the magnetic fan 10, the magnetic fan 10 can rotate around the first fixing shaft 61, one end of the second fixing shaft 62 is connected to the second sealed housing 105, the other end of the second fixing shaft is connected to the driving device 30, the magnetic structure 20 is fixedly connected to the second fixing shaft 62, and the driving device 30 can drive the second fixing shaft 62 to rotate, so as to drive the magnetic structure 20 to rotate.

Generally, the size of the magnetic blade 10 should not exceed the size of the magnetic structure 20 in consideration of space limitations and the driving force strength provided by the magnetic structure 20. When the relative area between the magnetic fan blade 10 and the magnetic structure 20 is maximized, the magnetic force between the magnetic fan blade 10 and the magnetic structure 20 is strongest, the magnetic structure 20 has the best driving effect on the magnetic fan blade 10, and one way to maximize the relative area between the magnetic fan blade 10 and the magnetic structure 20 is to make the number, the installation position and the size of the fan blades of the magnetic fan blade 10 correspond to those of the magnetic structure 20.

For this reason, in the present embodiment, the first fixed shaft 61 and the second fixed shaft 62 are coaxially disposed. The second fixing shaft 62 is provided with a plurality of magnetic structures 20, and the magnetic fan blades 10 are provided with fan blades corresponding to the magnetic structures 20 in number and size. In addition, in the present embodiment, the first fixed shaft 61 and the second fixed shaft 62 are coaxially arranged, specifically, the central axis of the first fixed shaft 61 and the central axis of the second fixed shaft 62 are overlapped in a direction perpendicular to the side wall. Of course, in other embodiments of the present application, the first fixing shaft 61 and the second fixing shaft 62 may also be designed to be non-coaxial, as long as the magnetic fan blade 10 is ensured to rotate under the driving of the magnetic structure 20.

In addition, in order to avoid the interference of other magnetic components on the rotation of magnetic fan blade 10, in this embodiment, all other components including housing 1 should be made of non-magnetic material, and in this embodiment, housing 1 may be a sealed housing made of metal such as aluminum, copper, etc.

Based on the optical engine provided in the foregoing embodiments, the present application further provides a projection display system including the optical engine provided in any one of the foregoing embodiments.

The embodiments in the present specification are described in a progressive manner, and the same and similar parts among the embodiments are referred to each other, and each embodiment focuses on the differences from the other embodiments. In particular, for apparatus or system embodiments, since they are substantially similar to method embodiments, they are described in relative terms, as long as they are described in partial descriptions of method embodiments. The above-described embodiments of the apparatus and system are merely illustrative, and the units described as separate parts may or may not be physically separate, and the parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the modules may be selected according to actual needs to achieve the purpose of the solution of the present embodiment. One of ordinary skill in the art can understand and implement it without inventive effort.

The foregoing is merely a detailed description of the invention, and it should be noted that modifications and adaptations by those skilled in the art may be made without departing from the principles of the invention, and should be considered as within the scope of the invention.

Claims (10)

1. An optical engine, comprising:

the heat dissipation device comprises a shell and at least one group of heat dissipation devices;

the heat dissipation device comprises a magnetic fan blade arranged on the inner side of the shell, a magnetic structure arranged on the outer side of the shell and a driving device of the magnetic structure, wherein the magnetic fan blade is driven by the magnetic structure to rotate.

2. A light engine as recited in claim 1, further comprising a projection light source including at least a first optical component enclosed by a first sealed housing, wherein the heat sink is disposed on a sidewall of the first sealed housing.

3. An optical engine as recited in claim 1, further comprising a light engine, said light engine including at least a second optical assembly enclosed by a second sealed housing, said heat sink being disposed on a sidewall of said second sealed housing.

4. The optical engine as claimed in claim 3, wherein the optical assembly includes a light guide, a lens set, a reflector set and a TIR total reflection prism sequentially arranged along a light propagation direction, the light guide, the lens set and the reflector set are sequentially arranged along a horizontal direction, the TIR total reflection prism is arranged perpendicular to the reflector set, and the magnetic fan blades are arranged on a side wall close to the lens set.

5. The optical engine of claim 4, wherein the magnetic fan is located corresponding to the light pipe.

6. The optical engine of claim 3,

the optical component is sequentially provided with a light guide pipe, a lens group, a reflector group and a TIR total reflection prism along a light propagation direction, the light guide pipe, the lens group and the reflector group are sequentially arranged along a horizontal direction, and the TIR total reflection prism is vertically arranged with the reflector group;

the optical engine comprises two groups of heat dissipation devices, wherein a first heat dissipation device is arranged on a first side wall close to the lens group, a second heat dissipation device is arranged on a second side wall close to a light inlet of the light guide pipe, and the second heat dissipation device corresponds to the position of the TIR total reflection prism;

the third side wall opposite to the second side wall comprises two parallel surfaces arranged in parallel with the second side wall and an inclined surface arranged between the two parallel surfaces.

7. The optical engine of claim 3, wherein the heat sink further comprises a first stationary shaft and a second stationary shaft, wherein,

one end of the first fixing shaft is connected with the second sealing shell, and the other end of the first fixing shaft is connected with the magnetic fan blade;

one end of the second fixed shaft is connected with the second sealing shell, the other end of the second fixed shaft is connected with the driving device, and the magnetic structure is fixedly connected with the second fixed shaft;

the first fixed shaft and the second fixed shaft are coaxially arranged.

8. The optical engine of claim 7, wherein the second fixed shaft is provided with a plurality of magnetic structures, and the magnetic fan blades are provided with fan blades corresponding to the number and size of the magnetic structures.

9. A light engine as recited in claim 1, wherein the housing is a non-magnetic material.

10. A projection display system comprising the optical engine of any of claims 1-9.

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